DE10162162A1 - Torsional vibration damper, in particular dual mass flywheel - Google Patents

Abstract

A torsional vibration damper, in particular a dual mass flywheel, has a primary (1) and a secondary side (2) which can be rotated about an axis of rotation (3) relative to the primary side (1). From a rotation in a direction of rotation (x) by a foreground angle (gamma), a foreground spring arrangement (9) exerts a foreground restoring force on the secondary side (2), from a rotation by an additional angle (delta) that is greater than the foreground angle (gamma) , an additional spring arrangement (8) additionally an additional restoring force. When rotating by a pre-limiting angle (epsilon), both spring arrangements (8, 9) jointly stop.

Description

• - wobei die Sekundärseite relativ zur Primärseite um eine Drehachse verdrehbar ist,
• - wobei ab einer Verdrehung in einer Drehrichtung um einen Vorgrundwinkel eine Vorgrundfederanordnung eine Vorgrundrückstellkraft auf die Sekundärseite ausübt,
• - wobei ab einer Verdrehung in der Drehrichtung um einen Vorzusatzwinkel eine Vorzusatzfederanordnung zusätzlich eine Vorzusatzrückstellkraft auf die Sekundärseite ausübt,
• - wobei der Vorzusatzwinkel größer als der Vorgrundwinkel ist.

The present invention relates to a torsional vibration damper, in particular a dual-mass flywheel, with a primary and a secondary side,

• the secondary side being rotatable about an axis of rotation relative to the primary side,
• where a fore spring arrangement exerts a fore restoring force on the secondary side from a rotation in a direction of rotation by a fore angle,
• - From a rotation in the direction of rotation by an additional angle, an additional spring arrangement additionally exerts an additional restoring force on the secondary side,
• - The additional angle is larger than the primary angle.

Torsional vibration dampers are in particular between a crankshaft Internal combustion engine and a gearbox used to move from the Keep internal combustion engine caused torsional vibrations away from the transmission. When reversing the load direction from thrust to train cause conventional Torsional vibration damper in the internal combustion engine a jerk that of a monitoring sensor system of the internal combustion engine incorrectly can be interpreted as a misfire. To get the jerk on one To keep the load direction reversal as small as possible, the above are described torsional vibration damper used. Such one Torsional vibration damper with so-called asymmetrical control is such. B. from DE 199 58 814 A1 of the applicant.

Long-term trials have shown that these are Torsional vibration dampers can cause fatigue fractures of the spring assemblies lead to failure of the torsional vibration damper.

The object of the present invention is a generic Torsional vibration damper to develop such that it is a larger Has lifespan.

The task is solved by turning around in the direction of rotation a pre-limiting angle the foreground spring arrangement and the Additional spring arrangement go together to the stop.

Because the inventors have found that fatigue fractures are due to it must be managed that in the event of overload of the torsional vibration damper in the state Technique only one of the spring assemblies goes to a stop while the other Spring arrangement still a further rotation of the secondary side relative to Primary side. The spring arrangement, which goes to stops, is therefore in State of the art significantly more stressed than the other spring arrangement, so that it breaks sooner.

On the other hand, due to the configuration according to the invention, also at Overload a load distribution on both spring assemblies, increasing the lifespan of the torsional vibration damper can be increased.

Theoretically, it is possible to arrange the spring in the same angular range to be arranged (e.g. axially offset from each other) and different Control elements to control. In practice, however, this is usually the case Additional spring arrangement arranged relative to the axis of rotation in a different angular range than that Vorgrundfederanordnung.

The spring arrangements usually have spring elements and Guide elements on which the spring elements are supported. Such Design is particularly durable and works very smoothly. The Guide elements include at least outer guide elements that adhere to each other Support points on the primary side and / or on driving elements on the secondary side support.

If adjacent guide elements are rotated by the pre-limit angle Vorgrundfederanordnung and adjacent guide elements of the Contact additional spring arrangement to each other, is the common opening of the Spring arrangement on reaching the pre-limit angle in a particularly simple manner Way feasible. In addition, the spring elements can be in this case be designed so that individual turns of the (screw) spring elements do not touch.

As a rule, the additional angle is only slightly larger than that Vorgrundwinkel. The primary spring arrangement and the auxiliary spring arrangement can therefore have substantially the same effective angle of rotation when the Support points on the primary side by a support point angle and Driving elements on the secondary side against each other by a driving element angle are arranged offset, the support point angle equal to that Driving element angle is, the guide elements have effective guide element lengths and the sum of the effective guide element lengths of the Vorgrundfederanordnung equal to the sum of the effective guide element lengths of Additional spring arrangement is.

If the effective guide element lengths of the guide elements of the Vorgrundfederanordnung and the auxiliary spring arrangement are the same in pairs can be guaranteed in a particularly simple manner that the sums of the effective Guide element lengths are the same.

If the guide elements from a base polymer, carbon fiber and one of Carbon fiber different dry lubricant exist, the share of Carbon fiber between 10 and 50 percent by weight and the proportion of Dry lubricant is a maximum of 30 percent by weight, are the guide elements Can be moved with little friction even after long periods of operation. Regarding more concrete preferred percentages will be the older, not pre-published German Patent application DE 100 59 709.2 of the applicant, in particular its Claims 2 to 7 referenced.

• - dass ab einer Verdrehung entgegen der Drehrichtung um einen Rückgrundwinkel eine Rückgrundfederanordnung eine Rückgrundrückstellkraft auf die Sekundärseite ausübt,
• - dass ab einer Verdrehung entgegen der Drehrichtung um einen Rückzusatzwinkel eine Rückzusatzfederanordnung zusätzlich eine Rückzusatzrückstellkraft auf die Sekundärseite ausübt,
• - dass der Rückzusatzwinkel größer als der Rückgrundwinkel ist und
• - dass bei Verdrehen entgegen der Drehrichtung um einen Rückgrenzwinkel die Rückgrundfederanordnung und die Rückzusatzfederanordnung gemeinsam auf Anschlag gehen.

The above statements relate exclusively to a rotation of the secondary side relative to the primary side in the direction of rotation. With a rotation against the direction of rotation, it is possible to control the spring arrangements symmetrically. However, it is also possible to implement asymmetrical control even when rotating against the direction of rotation. In this case,

• that a back spring arrangement exerts a back restoring force on the secondary side from a rotation against the direction of rotation by a back angle,
• that from a rotation counter to the direction of rotation by a reset angle, a reset spring arrangement additionally exerts a reset restoring force on the secondary side,
• - that the back angle is larger than the back angle and
• - That when rotating against the direction of rotation by a return limit angle, the back spring arrangement and the return additional spring arrangement together stop.

The back spring arrangement can optionally with the Foreground spring arrangement or the auxiliary spring arrangement be identical. The Return spring arrangement is identical to the other spring arrangement.

Further advantages and details emerge from the following Description of an embodiment in conjunction with the drawings. there show in principle

Fig. 1 a partial section through a torsional vibration damper,

Fig. 2 is a schematic representation of a section along the line II-II in Fig. 1,

Fig. 3 is a sectional view of the torsional vibration damper of FIG. 1 along the line III-III,

FIGS. 4 and 5, an outer guide member and

FIGS. 6 to 8 are schematic representations of the dynamic damper of FIG. 3.

Referring to FIGS. 1 and 2, a dual-mass flywheel as an example of a torsional vibration damper on a primary side and a secondary side 1 2. The secondary side 2 can be rotated about an axis of rotation 3 relative to the primary side 1 .

Referring to FIGS. 2 and 3 1 support points 4, 5 are arranged on the primary side. The support points 4 , 5 are offset from one another by a support point angle α of 180 °. Driving elements 6 , 7 are arranged on the secondary side 2 and are offset from one another by a driving element angle β. The driving element angle β is also 180 °. The support point angle α and the driving element angle β are therefore the same size.

According to FIG. 3, spring arrangements 8 , 9 have spring elements 10 , inner guide elements 11 and outer guide elements 12 , 13 . The spring elements 10 are supported on the guide elements 11 , 12 , 13 . The spring arrangements 8 , 9 are also supported on the support points 4 , 5 and / or on the driving elements 6 , 7 via the outer spring elements 12 , 13 .

As can be seen, the spring arrangements 8 , 9 are arranged in different angular ranges I, II relative to the axis of rotation 3 .

The guide elements 11 , 12 , 13 preferably consist of a base polymer, carbon fiber and a dry lubricant different from carbon fiber. As a base polymer z. B. a thermoplastic, in particular a polyamide. The proportion of carbon fiber is typically between 10 percent by weight and 50 percent by weight, in particular between 20 and 30 percent by weight. The proportion of dry lubricant other than carbon fiber is typically between 5 percent by weight and 15 percent by weight. Molybdenum disulfide and polytetrafluoroethylene (Teflon) are particularly suitable as the dry lubricant.

The inner guide elements 11 are all of the same design. In particular, they thus have effective inner guide element lengths l1 which are the same for all inner guide elements 11 .

The outer guide elements 12 , 13 also have effective outer guide element lengths l2. However, the outer guide elements 12 , 13 are not all of the same design. Namely, the two outer guide elements 12 arranged in the angular range I, that is to say the outer guide elements 12 of the left spring arrangement 8 according to FIG. 3, are designed as described below in connection with FIGS. 4 and 5.

Referring to FIGS. 4 and 5, these two outer guide elements 12 on the support points 4, 5 and the driving elements 6, 7 through recesses 14, between which extends a groove 15. The groove 15 is so wide that the driver elements 6 , 7 can dip into the groove 15 . The effective outer guide element length l2 of the guide elements 12 can thus be calculated from the bottom of the groove 15 .

The outer guide elements 13 of the other spring arrangement 9 have no such groove 15 . The effective outer guide element length l2 is to be calculated from paragraph 14 onwards. However, these outer guide elements 13 are also dimensioned such that their outer guide element length l2 is equal to the outer guide element length l2 of the other outer guide elements 12 . The effective guide element lengths l1, l2 of the guide elements 11 to 13 of the spring arrangements 8 , 9 are therefore identical in pairs. Thus, the sum of the effective guide element lengths l1, l2 of one spring arrangement 8 is also the sum of the effective guide element lengths l1, l2 of the other spring arrangement 9 .

The situation described above, in particular the presence of the grooves 15, is shown again schematically in FIG. 6. The grooves 15 of the outer guide elements 12 are shown in broken lines in FIG. 6.

As can be seen from FIGS. 2, 3 and 6, the driving elements 6 , 7 are dimensioned slightly shorter than the support points 4 , 5 . The secondary side 2 can therefore be rotated relative to the primary side 1 in a direction of rotation x by a small angle γ, hereinafter referred to as the foreground angle γ, without force. Upon reaching the γ Vorgrundwinkels the carrier element 6 is but at the upper outer guide member 13 of the right spring arrangement according to FIGS. 3 and 6 at. With a further rotation in the direction of rotation x, the right spring arrangement 9 thus exerts a basic restoring force on the secondary side 2 .

When a slightly larger angle δ, hereinafter referred to as additional angle δ, is reached, the lower driving element 7 of the secondary side 2 reaches the bottom of the groove 15 of the lower outer guide element 12 of the left spring arrangement 8 . Upon further rotation in the direction of rotation x, not only the right spring arrangement 9 , but also the left spring arrangement 8 is thus deflected from its rest position. Thus, from a rotation in the direction of rotation x by the additional angle δ, an additional additional restoring force acts on the secondary side 2 in addition to the primary restoring force.

As already mentioned, the additional angle δ is slightly larger than that Foreground angle γ. The ground angle γ is typically in the range between one and two degrees, the additional angle δ in the range between two and four Degree. However, the additional angle δ is always greater than the primary angle γ.

Upon further rotation in the direction of rotation x, the spring elements 10 are compressed until the secondary side 2 is rotated relative to the primary side 1 by a pre-limiting angle ε. This angle ε is defined in that at this angle ε adjacent guide elements 11 , 12 of the left spring arrangement 8 contact one another. The left spring arrangement 8 therefore stops when the pre-limit angle ε is reached.

As mentioned above, the sum of the effective guide element lengths l1, l2 of the guide elements 11 , 12 of the left spring arrangement 8 is equal to the sum of the effective guide element lengths l1, l2 of the guide elements 11 , 13 of the right spring arrangement 9 . When the pre-limit angle ε is reached, adjacent guide elements 11 , 13 of the right spring arrangement 9 also contact one another. Thus, both spring assemblies 8 , 9 together stop when the pre-limit angle ε is reached. This position is shown schematically in FIG. 7.

What was described above in connection with a rotation in the direction of rotation x applies due to the presence of two outer guide elements 12 with a groove 15 even when rotating against the direction of rotation x. Due to the specific design, the basic, additional and critical angles γ, δ, ε are the same in amount as in the case of a rotation in the direction of rotation. In principle, however, they could also be chosen differently.

In the embodiment described in connection with FIG. 6, namely the provision of outer guide elements 12 with a groove 15 both at the upper and at the lower end of the left spring arrangement 8 , regardless of whether the secondary side 2 is in or against relative to the primary side 1 the direction of rotation x is rotated, the right spring assembly 9 is always deflected first. The left spring arrangement 8 is deflected only later.

However, it is also possible to arrange the two guide elements 12 with shoulders 14 and groove 15 on the left and right of the same driving element 6 , 7 . This is shown in FIG. 8 for an arrangement on the left and right of the upper driving element 6 . In this case, the left spring arrangement 8 is first deflected from its rest position when it is rotated in the direction of rotation x. In the event of a rotation counter to the direction of rotation x, the right spring arrangement 9 is first deflected from its rest position. This procedure is completely equivalent to the procedure described above in connection with FIGS. 6 and 7.

The present invention thus ensures a simple distribution of the effective forces between the two spring arrangements 8 , 9 , in particular even when an overload occurs. The maximum load for one of the spring arrangements 8 , 9 is thus practically halved. This significantly increases the life of the torsional vibration damper as a whole. Reference number list 1 primary side
2 secondary side
3 axis of rotation
4 , 5 support points
6 , 7 driving elements
8 , 9 spring arrangements
10 spring elements
11 inner guide elements
12 , 13 outer guide elements
14 paragraphs
15 grooves
I, II angular ranges
l1, l2 guide element lengths
x direction of rotation
α-ε angle

Claims (11)

1. torsional vibration damper, in particular dual-mass flywheel, with a primary ( 1 ) and a secondary side ( 2 ),
the secondary side ( 2 ) being rotatable about an axis of rotation ( 3 ) relative to the primary side ( 1 ),
wherein from a rotation in a direction of rotation (x) by a foreground angle (γ) a foreground spring arrangement ( 9 ) exerts a foreground restoring force on the secondary side ( 2 ),
where from a rotation in the direction of rotation (x) by an additional angle (δ) an additional spring arrangement ( 8 ) additionally exerts an additional restoring force on the secondary side ( 2 ),
the additional angle (δ) being greater than the basic angle (γ),
characterized by
that when rotating in the direction of rotation (x) by a pre-limiting angle (ε), the primary spring arrangement ( 8 , 9 ) and the auxiliary spring arrangement ( 8 , 9 ) jointly stop. 2. Torsional vibration damper according to claim 1, characterized in that the auxiliary spring arrangement ( 8 ) is arranged relative to the axis of rotation ( 3 ) in a different angular range (I) than the primary spring arrangement ( 9 ). 3. Torsional vibration damper according to claim 1 or 2, characterized in that the spring arrangements ( 8 , 9 ) have spring elements ( 10 ) and guide elements ( 11 , 12 , 13 ) on which the spring elements ( 10 ) are supported. 4. Torsional vibration damper according to claim 3, characterized in that the guide elements ( 11 , 12 , 13 ) comprise at least outer guide elements ( 12 , 13 ) which are located at support points ( 4 , 5 ) on the primary side ( 1 ) and / or on driving elements ( 6 , 7 ) of the secondary side ( 2 ). 5. Torsional vibration damper according to claim 4, characterized in that when rotating by the pre-limit angle (γ) adjacent guide elements ( 11 , 13 ) of the main spring arrangement ( 9 ) and adjacent guide elements ( 11 , 12 ) of the auxiliary spring arrangement ( 8 ) contact each other. 6. Torsional vibration damper according to claim 5, characterized in that the support points ( 4 , 5 ) on the primary side ( 1 ) by a support point angle (α) and the driving elements ( 6 , 7 ) on the secondary side ( 2 ) by a driving element angle (β) are arranged offset against each other, that the support point angle (α) is equal to the driving element angle (β), that the guide elements ( 11 , 12 , 13 ) have effective guide element lengths (l1, l2) and that the sum of the effective guide element lengths (l1, l3) The primary spring arrangement ( 9 ) is equal to the sum of the effective guide element lengths (l1, l2) of the auxiliary spring arrangement ( 8 ). 7. torsional vibration damper according to claim 6, characterized in that the effective guide element lengths (l1, l2) of the guide elements ( 11 , 12 , 13 ) of the primary spring arrangement ( 9 ) and the auxiliary spring arrangement ( 8 ) are identical in pairs. 8. torsional vibration damper according to one of claims 3 to 7, characterized in that the guide elements ( 11 , 12 , 13 ) consist of a base polymer, carbon fiber and a different from carbon fiber dry lubricant, the proportion of carbon fiber between 10 and 50 percent by weight and the proportion of dry lubricant is a maximum of 30 percent by weight. 9. torsional vibration damper according to one of the above claims, characterized in
that from a rotation against the direction of rotation (x) by a background angle (γ) a background spring arrangement ( 8 , 9 ) exerts a background restoring force on the secondary side ( 2 ),
that from a rotation counter to the direction of rotation (x) by an additional angle (δ), an additional spring arrangement ( 8 , 9 ) additionally exerts an additional restoring force on the secondary side ( 2 ),
that the back angle (δ) is larger than the back angle (γ) and
that when rotating against the direction of rotation (x) by a return limit angle (ε), the back spring arrangement ( 8 , 9 ) and the return additional spring arrangement ( 8 , 9 ) jointly stop. 10. torsional vibration damper according to claim 9, characterized in that the foreground spring arrangement ( 9 ) with the back spring arrangement ( 8 , 9 ) and the auxiliary spring arrangement ( 8 ) with the return auxiliary spring arrangement ( 8 , 9 ) are identical. 11. Torsional vibration damper according to claim 9, characterized in that the foreground spring arrangement ( 9 ) with the back auxiliary spring arrangement ( 8 , 9 ) and the auxiliary spring arrangement ( 8 ) with the back spring arrangement ( 8 , 9 ) are identical.